JP6601729B2 - Data generation method, data reproduction method, data generation device, and data reproduction device - Google Patents

Description

  The present invention relates to a data generation method, a data reproduction method, a data generation device, and a data reproduction device.

  Non-Patent Documents 1 to 3 include techniques for generating, encoding, and multiplexing video.

ITU-TH. 265 "High efficiency video coding", October 2014 Recommendation ITU-R BT. 709-5 (04/2002) “Parameter values for the HDTV standards for production and international program exchange” Recommendation ITU-R BT. 2020-1 (06/2014) “Parameter values for ultra-high definition television systems for production and international program exchange”

  In such generation of video data, a new method has always been devised, but it is desired that backward compatibility with conventional devices can be realized.

  Accordingly, an object of the present invention is to provide a data generation method, a data reproduction method, a data generation device, or a data reproduction device that can realize backward compatibility.

  In order to achieve the above object, a data generation method according to an aspect of the present invention is video data of a second luminance dynamic range wider than the first luminance dynamic range, and is used to reproduce an image of the second luminance dynamic range. A data generation method for generating video data that is compatible with playback on a first device that is not compatible and that is compatible with video playback of the first brightness dynamic range, When a second device that supports video playback decodes the video data, a second OETF (Opto-Electric Transfer Function) that is referred to by the second device is used to generate a video signal included in the video data. A first step referred to by the first device when the first device decodes the video data. Storing first transfer function information for specifying OETF in VUI (Video Usability Information) in the video data; and second transfer function information for specifying the second OETF in the video data. And storing in SEI (Supplemental enhancement information).

  The data reproduction method according to an aspect of the present invention is video data having a second luminance dynamic range wider than the first luminance dynamic range, does not support reproduction of an image having the second luminance dynamic range, and A data playback method for playing back video data compatible with playback on a first device that supports playback of a video having a first luminance dynamic range, wherein the video data is stored in the first device by the first device. VUI (Video Usability Information) for storing first transfer function information for specifying a first OETF (Opto-Electrical Transfer Function) referred to by the first device when decoding the video, and the second luminance dynamic A second device that supports playback of range images is SEI (Supplemental enhancement information) in which second transfer function information for specifying the second OETF referred to by the second device when decoding the image data is stored, and the data reproduction method includes the SEI Acquiring the second transfer function information included in the video data, and reproducing the video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information.

  These general or specific aspects may be realized by a system, a method, an integrated circuit, a computer program, or a recording medium such as a computer-readable CD-ROM. The system, method, integrated circuit, computer program Also, any combination of recording media may be realized.

  The present invention can provide a data generation method, a data reproduction method, a data generation device, or a data reproduction device that can realize backward compatibility.

FIG. 1 is a diagram illustrating a configuration of a system according to an embodiment. FIG. 2 is a diagram illustrating an example of the OETF according to the embodiment. FIG. 3 is a diagram illustrating a configuration example of the VUI according to the embodiment. FIG. 4 is a diagram illustrating an example of the OETF according to the embodiment. FIG. 5 is a diagram illustrating an extension example of the OETF according to the embodiment. FIG. 6 is a diagram illustrating a configuration example of the SEI message according to the embodiment. FIG. 7 is a diagram illustrating a configuration example of the SEI message according to the embodiment. FIG. 8 is a diagram illustrating a configuration example of the SPS according to the embodiment. FIG. 9 is a diagram illustrating a configuration example of a hybrid descriptor according to the embodiment. FIG. 10 is a diagram illustrating a configuration example of a hybrid descriptor according to the embodiment. FIG. 11 is a diagram illustrating a configuration example of the HEVC descriptor according to the embodiment. FIG. 12 is a diagram illustrating operations of the stream and data reproduction device according to the embodiment. FIG. 13 is a flowchart illustrating the operation of the data generation device according to the embodiment. FIG. 14 is a flowchart showing the operation of the data reproducing apparatus according to the embodiment.

(Knowledge that became the basis of the present invention)
Corresponds to the brightness range with the maximum brightness value expanded to express bright light such as specular reflection light that cannot be expressed with the current TV signal with more realistic brightness while maintaining the dark gradation in the conventional video HDR (High Dynamic Range) has attracted attention as a method that has been adopted. Specifically, the method of the luminance range supported by conventional TV signals is called SDR (Standard Dynamic Range), and the maximum luminance value was 100 nits, whereas in HDR, the maximum is up to 1000 nits or more. It is assumed that the luminance value is enlarged.

  On the other hand, it is desired that such video data compatible with HDR can be reproduced even with a conventional reproduction apparatus compatible with SDR. That is, there is a demand for video data that can reproduce HDR video on a playback device that supports HDR, and that can play back SDR video on a playback device that supports SDR.

  A data generation method according to an aspect of the present invention is video data having a second luminance dynamic range wider than the first luminance dynamic range, does not support playback of an image having the second luminance dynamic range, and A data generation method for generating video data that is compatible with playback on a first device that supports playback of a video with a brightness dynamic range, and that supports playback of a video with the second brightness dynamic range. Generating a video signal included in the video data using a second OETF (Opto-Electrical Transfer Function) referred to by the second device when the second device decodes the video data; Specifies a first OETF that is referred to by the first device when the video data is decoded. One transfer function information is stored in VUI (Video Usability Information) in the video data, and second transfer function information for specifying the second OETF is stored in SEI (Supplemental enhancement information) in the video data. Storing.

  According to this, in a device that supports only the reproduction of the video with the first luminance dynamic range, the video data can be reproduced using the first transfer function information, and the reproduction of the video with the second luminance dynamic range is supported. In the device, the video data can be reproduced using the second function information. Thus, the data generation method can generate video data having backward compatibility.

  For example, the data generation method may further include a step of storing hybrid information indicating whether the video data is video data of the second luminance dynamic range in a multiplexing layer descriptor.

  According to this, in a data reproducing apparatus that reproduces video data, it is possible to prepare for switching of a reproduction method in advance using the hybrid information in the multiplexed layer. Thereby, it is possible to smoothly switch the reproduction method in the data reproduction apparatus.

  For example, the first OETF is defined by a linear term of the luminance of the video data in a first range of the luminance of the video data, and is a power of the luminance of the video data in a second range larger than the first range. It may be OETF specified in the section.

  For example, the second OETF is defined by a linear term of the luminance of the video data in a third range of the luminance of the video data, and is a power of the luminance of the video data in a fourth range larger than the third range. The fifth range may be OETF defined by the logarithm term of the luminance of the video data in a fifth range larger than the fourth range.

  For example, the first OETF may be an OETF defined by a power term of luminance of the video data.

  For example, the second OETF is defined by a power exponent of the luminance of the video data in the sixth range of the luminance of the video data, and is a logarithm of the luminance of the video data in the seventh range larger than the sixth range. It may be OETF specified in the section.

  For example, the first OETF is BT. 709 or BT. The OETF defined in 2020, and the second OETF may be a hybrid gamma OETF.

  For example, the data generation method may further include storing dynamic range increase information indicating a difference between a luminance dynamic range of the video data and the first luminance dynamic range in the SEI.

  For example, the data generation method may further include a step of storing, in the SEI, picture maximum average level information indicating a maximum average luminance value among average luminance values of all the pictures included in the video sequence. .

  The data reproduction method according to an aspect of the present invention is video data having a second luminance dynamic range wider than the first luminance dynamic range, does not support reproduction of an image having the second luminance dynamic range, and A data playback method for playing back video data compatible with playback on a first device that supports playback of a video having a first luminance dynamic range, wherein the video data is stored in the first device by the first device. VUI (Video Usability Information) for storing first transfer function information for specifying a first OETF (Opto-Electrical Transfer Function) referred to by the first device when decoding the video, and the second luminance dynamic A second device that supports playback of range images is SEI (Supplemental enhancement information) in which second transfer function information for specifying the second OETF referred to by the second device when decoding the image data is stored, and the data reproduction method includes the SEI Acquiring the second transfer function information included in the video data, and reproducing the video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information.

  According to this, the data reproduction method can reproduce video data having backward compatibility.

  For example, the video data further includes hybrid information stored in a multiplexing layer descriptor indicating whether the video data is video data of the second luminance dynamic range, and the data The reproduction method further includes a step of acquiring the hybrid information from the video data, and preparing to switch between reproduction of the first luminance dynamic range and reproduction of the second luminance dynamic range based on the acquired hybrid information. And a step of switching between reproduction of the first luminance dynamic range and reproduction of the second luminance dynamic range at a timing when the video sequence is switched.

  According to this, it is possible to prepare in advance for switching of the playback method using the hybrid information in the multiplexing layer. Thereby, the switching of the reproduction method can be performed smoothly.

  For example, the first OETF is defined by a linear term of the luminance of the video data in a first range of the luminance of the video data, and is a power of the luminance of the video data in a second range larger than the first range. It may be OETF specified in the section.

  For example, the second OETF is defined by a linear term of the luminance of the video data in a third range of the luminance of the video data, and is a power of the luminance of the video data in a fourth range larger than the third range. The fifth range may be OETF defined by the logarithm term of the luminance of the video data in a fifth range larger than the fourth range.

  For example, the first OETF may be an OETF defined by a power term of luminance of the video data.

  For example, the second OETF is defined by a power exponent of the luminance of the video data in the sixth range of the luminance of the video data, and is a logarithm of the luminance of the video data in the seventh range larger than the sixth range. It may be OETF specified in the section.

  For example, the first OETF is BT. 709 or BT. The OETF defined in 2020, and the second OETF may be a hybrid gamma OETF.

  For example, the data reproduction method may further include a step of acquiring, from the SEI, dynamic range increase information indicating a difference between a luminance dynamic range of the video data and the first luminance dynamic range.

  For example, the data reproduction method may further include a step of acquiring, from the SEI, picture maximum average level information indicating a maximum average luminance value among average luminance values of all the pictures included in the video sequence. .

  The data generation device according to an aspect of the present invention is video data having a second luminance dynamic range wider than the first luminance dynamic range, does not support reproduction of an image having the second luminance dynamic range, and A data generation device that generates video data compatible with playback on a first device that supports playback of a video with a first luminance dynamic range, and that supports playback of a video with the second luminance dynamic range. A generating unit that generates a video signal included in the video data using a second OETF (Opto-Electrical Transfer Function) referred to by the second device when the second device decodes the video data; To identify the first OETF referred to by the first device when the first device decodes the video data The first transfer function information is stored in a VUI (Video Usability Information) in the video data, and the second transfer function information for specifying the second OETF is set in the SEI (Video Usability Information) in the video data. And a second storage unit for storing in supplemental enhancement information.

  According to this, in a device that supports only the reproduction of the video with the first luminance dynamic range, the video data can be reproduced using the first transfer function information, and the reproduction of the video with the second luminance dynamic range is supported. In the device, the video data can be reproduced using the second function information. As described above, the data generation apparatus can generate video data having backward compatibility.

  The data reproduction apparatus according to an aspect of the present invention is video data having a second luminance dynamic range wider than the first luminance dynamic range, does not support reproduction of an image having the second luminance dynamic range, and A data playback apparatus for playing back video data compatible with playback on a first device that supports playback of a video having a first luminance dynamic range, wherein the video data is stored in the first device by the first device. VUI (Video Usability Information) for storing first transfer function information for specifying a first OETF (Opto-Electrical Transfer Function) referred to by the first device when decoding the video, and the second luminance dynamic A second device that supports playback of range images is SEI (supplemental enhancement information) in which second transfer function information for specifying the second OETF referred to by the second device when decoding the image data is stored, and the data reproducing device includes the SEI An acquisition unit for acquiring the second transfer function information included in the video data, and a playback unit for reproducing the video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information. Including.

  According to this, the data reproducing apparatus can reproduce video data having backward compatibility.

  Note that these comprehensive or specific aspects may be realized by a system, a method, an integrated circuit, a computer program, or a recording medium such as a computer-readable CD-ROM, and the system, method, integrated circuit, and computer program. Also, any combination of recording media may be realized.

  Hereinafter, embodiments will be specifically described with reference to the drawings.

  Note that each of the embodiments described below shows a specific example of the present invention. The numerical values, shapes, materials, constituent elements, arrangement positions and connecting forms of the constituent elements, steps, order of steps, and the like shown in the following embodiments are merely examples, and are not intended to limit the present invention. In addition, among the constituent elements in the following embodiments, constituent elements that are not described in the independent claims indicating the highest concept are described as optional constituent elements.

  In the following, detailed descriptions of terms, data structures, processing contents, and the like may be omitted, but examples of these specific examples are disclosed in Non-Patent Document 1, Non-Patent Document 2, and Non-Patent Document 3, for example. Follow the description.

  First, the configuration of the system according to the present embodiment will be described. FIG. 1 is a block diagram showing a configuration of a system according to the present embodiment. The system shown in FIG. 1 includes a data generation device 110 and a data reproduction device 120.

  The data generation device 110 is video data having a second luminance dynamic range (for example, HDR) wider than the first luminance dynamic range (for example, SDR), does not support reproduction of an image having the second luminance dynamic range, and the first Video data that is compatible with playback on a first device that supports playback of video with a luminance dynamic range is generated.

  The data generation apparatus 110 includes a video signal generation unit 111, an encoding unit 112, and a multiplexing unit 113.

  The video signal generation unit 111 converts the luminance value of the original image corresponding to HDR into a code value using OETF (Opto-Electric Transfer Function). Here, OETF is a function for converting the luminance value of the original image into a code value, as shown in FIG. Specifically, the video signal generator 111 uses SDR compatible HDR OETF. Details of this will be described later.

  The encoding unit 112 generates a video elementary stream by encoding the obtained code value in accordance with a video encoding standard such as HEVC. The multiplexing unit 113 generates a transport stream (for example, a DVB transport stream) by multiplexing the video elementary stream.

  The generated transport stream is transmitted to the data reproduction device 120 by, for example, broadcast waves. Although an example in which broadcast waves are used is described here, transmission via a network or the like may be used, and transmission via a recording medium such as a BD disc may be used.

  The data playback device 120 plays back the video data generated by the data generation device 110. The data reproduction device 120 includes a demultiplexing unit 121, a decoding unit 122, and a reproduction unit 123.

  The demultiplexing unit 121 generates a video elementary stream by demultiplexing video data (transport stream). The decoding unit 122 generates a code value by performing decoding based on a video encoding standard such as HEVC on the obtained video elementary stream.

  The playback unit 123 restores the video by converting the obtained code value into a luminance value using EOTF (Electro-Optical Transfer Function) corresponding to the OETF. Here, EOTF is an inverse function of OETF and is a function for converting a code value into a luminance value. The obtained video is displayed on a display unit or the like included in or connected to the data reproduction device 120.

  Hereinafter, signaling of the transfer function (OETF) of the present embodiment will be described.

  The transfer function is signaled using transfer_characteristics in VUI (Video Usability Information) included in SPS (Sequence Parameter Set) in HEVC and AVC video coding standards.

  Also, only OETF is signaled and EOTF is not signaled.

  FIG. 3 is a diagram illustrating the syntax of the VUI parameter. As shown in FIG. 3, the VUI includes first transfer function information (transfer_characteristics). FIG. 4 is a table showing the meaning of transfer_characteristics. Values 1 and 14 are assigned to the SDR OETF supported by the Digital Video Broadcasting (DVB) Phase 1 receiver of UHD (Ultra HD).

  transfer_characteristics indicates an opto-electrical characteristic of the original image as described in Non-Patent Document 1 and the like.

  Signaling means that a signal for specifying the desired information or a signal indicating the information itself is included in the transmission signal so that the receiving side can acquire the desired information. For example, in the example of FIGS. 3 and 4, transfer_characteristics for specifying the OETF is included in the transfer signal, and the reception side specifies the OETF based on the received transfer_characteristics.

  Hereinafter, an example of extension for the new OETF according to the present embodiment will be described.

  In the HEVC and AVC standards, a reserved value (reserved) for further expansion is provided. Therefore, this spare value can be assigned to an SDR compatible HDR OETF (hereinafter referred to as hybrid OETF). For example, as shown in FIG. 5, the hybrid OETF is assigned to values 18 to 20 that are reserve values.

  However, in this case, an old specification data reproducing apparatus (receiver) that does not support HDR cannot recognize the new value and recognizes it as a preliminary value. As a result, there is a problem in that backward compatibility cannot be realized when a new value is used for the hybrid OETF. Here, the hybrid OETF is an OETF including a portion expressed by a power of luminance and a portion expressed by a logarithm of luminance, such as a BBC hybrid gamma (Hybrid Gamma) OETF.

  In the present embodiment, the value of the first transfer function information (transfer_characteristics) is set to 1 (BT.709) or 14 (BT.2020) similarly to the conventional SDR.

  In addition, second transfer function information (HDR_transfer_characteristic) is signaled separately from the first transfer function information in order to identify the hybrid OETF. As a result, the data reproducing apparatus that does not support HDR can identify the OETF for SDR using the first transfer function information (transfer_characteristics), and the data reproducing apparatus that supports HDR uses the second transfer function information. Use to identify the OETF for HDR.

  Here, the second transfer function information (HDR_transfer_characteristic) is used for signaling of the OETF for HDR. Specifically, the HDR OETF is compatible with the SDR OEFT specified by the first transfer function information (transfer_characteristics).

  For example, the second transfer function information (HDR_transfer_characteristic) indicates one of the three hybrid OETFs shown in FIG. The second transfer function information may be information indicating whether hybrid OETF is used. The number of hybrid OETFs that can be selected is arbitrary and may be one or more.

  In addition, as shown in FIG. 2, the characteristics of the hybrid OETF substantially match those of the SDR OETF in a low luminance range. In other words, when the video signal generated using the hybrid OETF is reproduced using the hybrid OETF and when the video signal is reproduced using the SDR OETF, the reproduced luminance is almost the same in the low luminance range. . Thereby, since the difference in luminance value between the case of being played back by the HDR device and the case of being played back by the SDR device can be reduced, it is possible to play a video with little sense of incongruity even when played back using the SDR OETF.

  Hereinafter, a plurality of methods for storing the second transfer function information will be described. Broadly speaking, there are a method for storing the second transfer function information in a video coding layer and a method for storing it in a multiplexing layer.

  First, a method for storing the second transfer function information in the video coding layer will be described.

  FIG. 6 is a diagram illustrating the syntax of an HDR hybrid gamma SEI message (hereinafter referred to as a hybrid SEI message) according to the present embodiment. As illustrated in FIG. 6, the second transfer function information (HDR_transfer_characteristic) is included in the hybrid SEI message.

  The hybrid SEI message exists only in the IRAP NAL unit or the I picture, and is valid for the subsequent encoded video sequence.

  The hybrid SEI message may be a prefix (prefix) or suffix (Suffix) SEI message.

  In the application standardized document, the presence of this SEI message may be made mandatory when HDR_transfer_characteristi has a predetermined fixed value.

  As shown in FIG. 7, the hybrid SEI message includes dynamic range increase information (dynamic_range_increase) and picture maximum average level information (maximum_average_picture_level) in addition to the second transfer function information or instead of the second transfer function information. May be included.

  The dynamic range increase information (dynamic_range_increase) is used for calculating the coefficient k and takes only a value of 0, 1 or 2. The coefficient k indicates a difference from the dynamic range of SDR and is obtained by the following (Equation 1). Specifically, the coefficient k indicates a magnification of the dynamic range of the video with respect to the SDR dynamic range.

    k = 2 × dynamic_range_increase + 4 (Expression 1)

  The picture maximum average level information (maximum_average_picture_level) indicates the maximum average picture level among all the pictures included in the video sequence. Here, the average picture level is an average value of luminance of pixels expressed as a percentage with respect to the maximum luminance.

  Thus, by using the dynamic range increase information and the picture maximum average level information, the difference from the SDR can be set to an arbitrary range.

  In the application standardized document, the presence of this SEI message may be made mandatory when k is a predetermined fixed value. For example, k = 4 for DVB and k = 8 for BDA.

  FIG. 8 is a diagram illustrating a configuration of an extended SPS. As shown in FIG. 8, dynamic range increase information (dynamic_range_increase) and picture maximum average level information (maximum_average_picture_level) may be included in the SPS.

  Next, a method for storing the second transfer function information in the multiplexing layer will be described.

  FIG. 9 is a diagram showing a configuration of a hybrid descriptor (HDR_hybrid_gamma_descriptor) that is a new MPEG2-TS level descriptor according to the present embodiment.

  As shown in FIG. 9, the hybrid descriptor includes a hybrid OETF flag (HDR_hybrid_gamma_OETF_flag) and second transfer function information (HDR_transfer_characteristic).

  The hybrid OETF flag (HDR_hybrid_gamma_OETF_flag) indicates whether the content is HDR-encoded using the hybrid OETF. For example, when the hybrid OETF flag is 1, the content is HDR-encoded using the hybrid OETF.

  Note that the hybrid OETF flag is not always necessary, and only the second transfer function information may be used.

  The hybrid descriptor is defined by PMT (Program Map Table) defined in MPEG, SDT (Service Description Table) defined in DVB within the DVB-SI standard, and DVB defined in the DVB-SI standard. Stored in at least one of EIT (Event Information Table).

  PMT indicates the PID of a TS packet storing an image or sound. The data reproduction apparatus can extract a TS packet of a desired image or sound by obtaining a PID such as a desired image or sound from the PMT.

  SDT indicates the name of a channel (service), the type of EIT transmitted in each channel, digital copy control information, and the like.

  EIT indicates information related to the program such as the name of the program, the broadcast date and time, and the broadcast content.

  When the PMT includes a hybrid descriptor, the hybrid descriptor is attached only to the video elementary stream. However, in this case, it is necessary to control the correction of the PMT at the broadcasting station, and this correction may be difficult.

  When the hybrid descriptor is included in the SDT, the contents of the hybrid descriptor are not frequently updated. Therefore, it is preferable when the contents of the hybrid descriptor are applied to the entire service.

  When the hybrid descriptor is included in the EIT, there is an advantage that the contents of the hybrid descriptor can be changed in units of events.

  FIG. 10 is a diagram showing another configuration of the hybrid descriptor according to the present embodiment. As shown in FIG. 10, the hybrid descriptor may include dynamic range increase information (dynamic_range_increase) and picture maximum average level information (maximum_average_picture_level) in addition to the second transfer function information or instead of the second transfer function information. Good.

  FIG. 11 is a diagram showing the configuration of the HEVC descriptor (HEVC_descriptor) according to the present embodiment. The HEVC descriptor is an MPEG2-TS level descriptor. As shown in FIG. 11, the preliminary value (reserved) of the HEVC descriptor is replaced with a hybrid encoding flag (hdr_hybrid_gamma_coded_content_flag) and dynamic range increase information (dynamic_range_increase). The hybrid encoding flag is the same flag as the hybrid OETF flag (HDR_hybrid_gamma_OETF_flag) described above. Further, the other information described above (second transfer function information and picture maximum average level information) may be included in the HEVC descriptor.

  Further, the same extension may be performed on the AVC descriptor (AVC_video_descriptor).

  Further, the above-described hybrid descriptor (HDR_hybrid_gamma_descriptor) and OETF signaling (hybrid SEI message) to the video elementary stream may be combined. Thereby, the parameter switching in the data reproducing apparatus can be performed smoothly.

  Hereinafter, this operation will be described in detail. FIG. 12 is a diagram illustrating a stream configuration and the operation of the data reproducing apparatus.

  The hybrid descriptor (HDR_hybrid_gamma_descriptor) including the hybrid OETF flag (HDR_hybrid_gamma_OETF_flag) starts to be transmitted shortly before the actual change. The data reproducing apparatus that has received this hybrid OETF flag prepares for a change between SDR and HDR.

  Further, in order to make the parameter change effective, an EOS (End Of Sequence) indicating the end of the video sequence is inserted into the video elementary stream. Further, a hybrid SEI message adapted to the hybrid descriptor signaled immediately before may or may not be stored in a RAP (random access point) subsequent to EOS.

  The data reproducing device detects whether or not an EOS and hybrid SEI message exist, and performs a change according to the detection result.

  In the example illustrated in FIG. 12, the data reproducing device acquires a hybrid descriptor including HDR_hybrid_gamma_OETF_flag = 0 in a state where the HDR operation is performed. As a result, the data reproducing apparatus starts preparation for switching the operation from HDR to SDR. Next, the data reproducing apparatus switches from HDR to SDR at the timing when EOS is acquired. Also, there is no hybrid SEI message in the SDR video elementary stream, and the data playback apparatus does not acquire the hybrid SEI message.

  Next, the data reproducing apparatus acquires a hybrid descriptor including HDR_hybrid_gamma_OETF_flag = 1 in a state where the SDR operation is performed. As a result, the data reproducing apparatus starts preparation for switching the operation from SDR to HDR. Next, the data reproducing apparatus switches from SDR to HDR at the timing when EOS is acquired.

  Hereinafter, operations of the data generation device 110 and the data reproduction device 120 based on the above will be described.

  FIG. 13 is a flowchart of the operation of the data generation apparatus 110 according to the present embodiment. The data generation device 110 generates HDR video data that is compatible with playback on a first device that does not support playback of HDR video and that supports playback of SDR video. To do.

  First, the video signal generation unit 111 generates a video signal by converting the luminance value of the original image into a code value using the second OETF (S101). Next, the encoding unit 112 generates a video elementary stream by encoding the video signal. At this time, the encoding unit 112 obtains the first transfer function information for identifying the first OETF referred to by the first device when the first device supporting only the SDR reproduces the video data as the video data ( Stored in the VUI in the video elementary stream. Further, the second transfer function information for specifying the second OETF referred to by the second device when the second device compatible with HDR decodes the video data is stored in the SEI in the video data (S102). ).

  Here, VUI and SEI belong to the video coding layer. The first OETF is, for example, BT. 709 or BT. The OETF specified in 2020, and the second OETF is, for example, a BBC hybrid gamma OETF.

  The encoding unit 112 may further store dynamic range increase information indicating a difference between the luminance dynamic range of the video data and the luminance dynamic range of the SDR in the SEI. Further, the encoding unit 112 may further store picture maximum average level information indicating the maximum average luminance value among the average luminance values of all the pictures included in the video sequence in the SEI.

  Next, the multiplexing unit 113 generates a transport stream by multiplexing the video elementary stream data. At this time, the multiplexing unit 113 stores hybrid information (hybrid OETF flag) indicating whether or not the video data is HDR video data in the hybrid descriptor of the multiplexing layer (S103).

  In the example illustrated in FIG. 12, the hybrid descriptor includes at least a hybrid OETF flag. However, the hybrid descriptor further includes second transfer function information, dynamic range increase information, or picture maximum average level information. May be included.

  Similarly, the hybrid SEI message may include at least one of a hybrid OETF flag, second transfer function information, dynamic range increase information, and picture maximum average level information.

  In the above description, the hybrid OETF flag and the second transfer function information are described as individual information. However, the second transfer function information may be used instead of the hybrid OETF flag. That is, the hybrid OETF flag may not be used. For example, depending on whether or not the second transfer function information is included in the video data, it is possible to signal whether or not the video data is HDR video data (whether or not hybrid OETF is used). Alternatively, whether the video data is HDR video data may be signaled depending on whether the second transfer function information indicates hybrid OETF or SDR OETF.

  In the above description, the example in which the hybrid OETF is indicated by the second transfer function information has been described. However, when HDR video and SDR video are mixed in the video data as shown in FIG. Also, the SDR OETF may be indicated by the second transfer function information for the video. As a result, in a data reproducing apparatus that supports HDR, it is only necessary to always refer to the second transfer function information regardless of whether the video data is SDR or HDR. That is, the data reproducing apparatus may not refer to the first transfer function information. Thereby, the processing of the data reproducing apparatus can be simplified.

  FIG. 14 is a flowchart of the operation of the data reproduction device 120 according to the present embodiment. The data playback device 120 plays back HDR video data that is compatible with playback on a first device that does not support playback of HDR video and that supports playback of SDR video. To do. Here, this video data is, for example, video data generated by the data generation device 110.

  First, the demultiplexing unit 121 generates a video elementary stream by demultiplexing video data (transport stream). At this time, the demultiplexing unit 121 acquires hybrid information (for example, a hybrid OETF flag) from the hybrid descriptor of the video data (S121). Note that the demultiplexer 121 may further acquire at least one of dynamic range increase information and picture maximum average level information from the hybrid descriptor.

  Next, the data reproducing device 120 prepares for switching between SDR reproduction and HDR reproduction based on the acquired hybrid information (S122).

  Next, the decoding unit 122 generates a video signal (code value) by decoding the video elementary stream. When the previous hybrid OETF flag indicates that the hybrid OETF is used, the decoding unit 122 acquires the second transfer function information included in the hybrid SEI in the video elementary stream (S123). Note that the decoding unit 122 may further acquire at least one of the dynamic range increase information and the picture maximum average level information from the hybrid SEI.

  The reproducing unit 123 reproduces the video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information (S124). Also, the playback unit 123 switches between SDR playback and HDR playback at the timing when the video sequence is switched. Specifically, the reproduction unit 123 reproduces data after EOS in the changed method. When dynamic range increase information or picture maximum average level information is acquired, playback is performed using these information.

  If the previous hybrid OETF flag indicates that the hybrid OETF is not used, in step S123, the decoding unit 122 acquires the first transfer function information included in the VUI in the video elementary stream. . In step S124, the reproducing unit 123 reproduces the video signal included in the video data with reference to the second OETF specified by the acquired first transfer function information. Note that, as described above, when the first OETF or the second OEFT is selectively indicated by the second transfer function information, the decoding unit 122 always acquires the second transfer function information, and the reproducing unit 123 receives the second transfer function information. You may refer to the first OETF or the second OETF indicated by the transfer function information.

  As described above, in this embodiment, in addition to the first transfer function information stored in the VUI, the second transfer function information is stored in the SEI message. Thereby, HDR encoding using hybrid OETF, such as BBC hybrid gamma (Hybrid Gamma) OETF, is realizable.

  Specifically, it is possible to indicate whether the content is HDR-encoded by hybrid OETF by signaling to the multiplexing layer using the descriptor.

  Also, smooth switching between HDR and SDR by the data reproducing apparatus can be realized by a combination of a new SEI message and a new descriptor.

The first OETF may be a function defined by the following (Formula 2).

  Here, L is the luminance of the image, and is normalized to 0 ≦ L ≦ 1 at the reference white level. V is a numerical value corresponding to the electrical signal. Α, β, γ, δ, and ρ are certain constants, and specific numerical examples include α = 4.5, β = 0.018, γ = 1.999, δ = 0.45, ρ = 0.099.

  That is, as shown in (Expression 2), the first OETF is defined by the linear term of the luminance of the video data in the first range of the luminance of the video data, and the video data in the second range larger than the first range. It may be OETF defined by a power term of luminance.

Further, the first OETF may be a function expressed by the following (Equation 3).

  Here, L is the luminance of the image, and is normalized by 0 ≦ L ≦ 1. E is a numerical value corresponding to the voltage normalized at the reference white level, and is proportional to the absolute light intensity detected in the reference camera color channel RGB. As a result, E 'becomes a non-linear signal. Also, α, β, γ, and δ are certain constants. Specific numerical examples include α = 4.5, β = 0.018 (for 10-bit system) or 0.0181 (for 12− bit system), γ = 1.099 (for 10-bit system) or 1.0993 (for 12-bit system), δ = 0.45, and ρ = 0.099.

  The second OETF may be a function defined by the following (Equation 4). In the OETF, the conversion function is defined by a logarithmic term at high luminance.

  Here, L is the luminance of the image and is standardized at the reference white level. However, L may exceed 1. That is, this conversion function also supports a brightness greater than that of reference white. V is a numerical value corresponding to the electrical signal. μ is a conversion point (breakpoint) between the gamma curve and the logarithmic curve, and determines the maximum value of L when V is 1 or less. Α, β, γ, δ, and ρ are certain constants, and specific numerical examples include α = 4.5, β = 0.018, γ = 1.999, δ = 0.45, ρ = 0.099.

  That is, as shown in (Expression 4), the second OETF is defined by the linear term of the luminance of the video data in the third range of the luminance of the video data, and the video data in the fourth range larger than the third range. OTF defined by the logarithm term of the luminance of the video data may be used in the fifth range larger than the fourth range.

  The first OETF may be a function defined by the following (Formula 5).

  Here, L is the luminance of the image, and is normalized to 0 ≦ L ≦ 1 at the reference white level. V is a numerical value corresponding to the electrical signal. Α is a constant, and α = 0.5 is a specific numerical example.

  That is, as shown in (Formula 5), the first OETF may be an OETF defined by a power term of the luminance of the video data.

  The second OETF may be a function defined by the following (Formula 6). In the OETF, the conversion function is defined by a logarithmic term at high luminance.

  Α is a constant, and α = 0.5 is a specific numerical example.

  In other words, as shown in (Equation 6), the second OETF is defined by the power of the luminance of the video data in the sixth range of the luminance of the video data, and the video data in the seventh range larger than the sixth range. OETF defined by the logarithm term of the luminance of the.

  As described above, the data generation apparatus (data generation method) and the data reproduction apparatus (data reproduction method) according to one or a plurality of aspects have been described based on the embodiment. However, the present invention is limited to this embodiment. It is not something. Unless it deviates from the gist of the present invention, various modifications conceived by those skilled in the art have been made in this embodiment, and forms constructed by combining components in different embodiments are also within the scope of one or more aspects. May be included.

  For example, in each of the above embodiments, each component may be configured by dedicated hardware such as a circuit, or may be realized by executing a software program suitable for each component. Each component may be realized by a program execution unit such as a CPU or a processor reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory.

  The present invention can be applied to a data reproducing apparatus such as a data transmitting apparatus or a BD device.

DESCRIPTION OF SYMBOLS 110 Data generation apparatus 111 Video signal generation part 112 Coding part 113 Multiplexing part 120 Data reproducing apparatus 121 Demultiplexing part 122 Decoding part 123 Reproducing part

Claims (20)

Video data having a second luminance dynamic range wider than the first luminance dynamic range, the video data not corresponding to the reproduction of the second luminance dynamic range, and corresponding to the reproduction of the image of the first luminance dynamic range. A data generation method for generating video data compatible with playback on a first device,
The video data using a second OETF (Opto-Electric Transfer Function) referred to by the second device when the second device corresponding to the reproduction of the video of the second luminance dynamic range decodes the video data. Generating a video signal included in;
A step of storing first transfer function information for identifying a first OETF referred to by the first device when the first device decodes the video data in a VUI (Video Usability Information) in the video data. When,
Storing second transfer function information for specifying the second OETF in SEI (Supplemental enhancement information) in the video data. The data generation method further includes:
The data generation method according to claim 1, further comprising the step of storing hybrid information indicating whether or not the video data is video data of the second luminance dynamic range in a descriptor of a multiplexing layer. The first OETF is defined by a linear term of the luminance of the video data in a first range of the luminance of the video data, and is a power of the luminance of the video data in a second range larger than the first range. It is a specified OETF,
The data generation method according to claim 1 or 2. The second OETF is defined by a linear term of the luminance of the video data in a third range of the luminance of the video data, and is a power term of the luminance of the video data in a fourth range larger than the third range. In a fifth range that is defined and larger than the fourth range, the OETF is defined by the logarithm term of the luminance of the video data.
The data generation method according to claim 1 or 2. The first OETF is an OETF defined by a power term of luminance of the video data.
The data generation method according to claim 1 or 2. The second OETF is defined by a power of the luminance of the video data in the sixth range of the luminance of the video data, and is a logarithmic term of the luminance of the video data in the seventh range larger than the sixth range. It is a specified OETF,
The data generation method according to claim 1 or 2. The first OETF is BT. 709 or BT. OETF specified in 2020,
The data generation method according to claim 1, wherein the second OETF is a hybrid gamma OETF. The data generation method further includes:
The data generation method according to claim 1, further comprising: storing, in the SEI, dynamic range increase information indicating a difference between a luminance dynamic range of the video data and the first luminance dynamic range. The data generation method further includes:
9. The method according to claim 1, further comprising: storing, in the SEI, picture maximum average level information indicating a maximum average luminance value among average luminance values of all the pictures included in the video sequence. Data generation method. Video data having a second luminance dynamic range wider than the first luminance dynamic range, the video data not corresponding to the reproduction of the second luminance dynamic range, and corresponding to the reproduction of the image of the first luminance dynamic range. A data playback method for playing back video data compatible with playback on a first device,
The video data is
When the first device decodes the video data, VUI (Video Usability Information) in which first transfer function information for specifying a first OETF (Opto-Electrical Transfer Function) referred to by the first device is stored is stored. )When,
Second transfer function information for specifying the second OETF referred to by the second device when the second device corresponding to the reproduction of the video of the second luminance dynamic range decodes the video data is stored. SEI (supplemental enhancement information)
The data reproduction method includes:
Obtaining the second transfer function information included in the SEI;
Replaying a video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information. The video data further includes
Including hybrid information stored in a descriptor of a multiplexing layer indicating whether the video data is video data of the second luminance dynamic range;
The data reproduction method further includes:
Obtaining the hybrid information from the video data;
Preparing to switch between reproduction of the first luminance dynamic range and reproduction of the second luminance dynamic range based on the acquired hybrid information;
The data reproduction method according to claim 10, further comprising a step of switching between reproduction of the first luminance dynamic range and reproduction of the second luminance dynamic range at a timing at which a video sequence is switched. The first OETF is defined by a linear term of the luminance of the video data in a first range of the luminance of the video data, and is a power of the luminance of the video data in a second range larger than the first range. It is a specified OETF,
The data reproduction method according to claim 10 or 11. The second OETF is defined by a linear term of the luminance of the video data in a third range of the luminance of the video data, and is a power term of the luminance of the video data in a fourth range larger than the third range. In a fifth range that is defined and larger than the fourth range, the OETF is defined by the logarithm term of the luminance of the video data.
The data reproduction method according to claim 10 or 11. The first OETF is an OETF defined by a power term of luminance of the video data.
The data reproduction method according to claim 10 or 11. The second OETF is defined by a power of the luminance of the video data in the sixth range of the luminance of the video data, and is a logarithmic term of the luminance of the video data in the seventh range larger than the sixth range. It is a specified OETF,
The data reproduction method according to claim 10 or 11. The first OETF is BT. 709 or BT. OETF specified in 2020,
The data reproduction method according to claim 10 or 11, wherein the second OETF is a hybrid gamma OETF. The data reproduction method further includes:
The data reproduction method according to claim 10, further comprising: acquiring dynamic range increase information indicating a difference between a luminance dynamic range of the video data and the first luminance dynamic range from the SEI. The data reproduction method further includes:
18. The method according to claim 10, further comprising: obtaining, from the SEI, picture maximum average level information indicating a maximum average luminance value among average luminance values of all the pictures included in the video sequence. Data playback method. Video data having a second luminance dynamic range wider than the first luminance dynamic range, the video data not corresponding to the reproduction of the second luminance dynamic range, and corresponding to the reproduction of the image of the first luminance dynamic range. A data generation device for generating video data compatible with reproduction on a first device,
The video data using a second OETF (Opto-Electric Transfer Function) referred to by the second device when the second device corresponding to the reproduction of the video of the second luminance dynamic range decodes the video data. A generator for generating a video signal included in
First transfer function information for specifying a first OETF referred to by the first device when the first device decodes the video data is stored in a VUI (Video Usability Information) in the video data. 1 storage unit;
And a second storage unit that stores second transfer function information for specifying the second OETF in SEI (Supplemental enhancement information) in the video data. Video data having a second luminance dynamic range wider than the first luminance dynamic range, the video data not corresponding to the reproduction of the second luminance dynamic range, and corresponding to the reproduction of the image of the first luminance dynamic range. A data playback device for playing back video data compatible with playback on a first device,
The video data is
When the first device decodes the video data, VUI (Video Usability Information) in which first transfer function information for specifying a first OETF (Opto-Electrical Transfer Function) referred to by the first device is stored is stored. )When,
Second transfer function information for specifying the second OETF referred to by the second device when the second device corresponding to the reproduction of the video of the second luminance dynamic range decodes the video data is stored. SEI (supplemental enhancement information)
The data reproduction device includes:
An acquisition unit for acquiring the second transfer function information included in the SEI;
A data reproduction apparatus comprising: a reproduction unit that reproduces a video signal included in the video data with reference to the second OETF specified by the acquired second transfer function information.

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